HU214479B - Tile retaining storm hook - Google Patents

Abstract

A storm hook (10) for retaining a tile (16) consists of a hook-like head (12) made of a flat material which can be hooked on the top side of a lapped tile (16), preferably into its water groove (14), and a foot (18) which can be directly linked to the head in a tension-resistant manner and which can be secured to the roof infrastructure (20). The head (12) may be linked to the foot (18) at a variable distance from the spot where the foot (18) is secured to the roof infrastructure (20). In order to create a storm hook which is easy to mount without tools on the top side of a roof, which can be used both for tiles with different profiles and for roof infrastructures of different sizes, in particular those with roof laths of different thicknesses and/or widths, and which can be secured to the roof infrastructure always with the maximum possible tensile force, the foot (18) is approximately L-shaped and its base leg (34) can be hooked at its free end (36) onto the roof infrastructure (20). A holder (28) for the long leg of the foot (18) is provided on a section (26) of the head (12) bent towards the foot (18). The upper end section (30) of the foot (18) which projects beyond the head (12) is bent directly above the holder (28) when the hook is mounted in its appropriate position, thus forming a tension-resistant connection.

Description

BACKGROUND OF THE INVENTION The present invention relates to a storm clamp for fixing a tile, which is formed on the top side of an overlapped tile, preferably in its water-conducting groove, by a hook-shaped head made of flat material and connected directly thereto in a tensile manner the head portion being formed to be interconnected with the foot portion at a variable distance relative to the location of the foot portion on the roof substructure.

According to the invention, a corrugated tile can be both a clay roof tile and a concrete roof tile. The lateral edge sections of a corrugated tile laid on a roof surface are formed on one side as a watertight groove and on the opposite side as a top groove. When viewed in the direction of the collar, the top groove is usually arranged to the right.

To cover a roof, the tile is usually laid in several rows running parallel to the ridge. Within a given row, the corrugated tiles are arranged side by side, where, apart from the gable edges, in the region of the lateral edge portions, a particular corrugated topsheet overlaps the water-conducting groove of the adjacent corrugated corrugation. The area of the lateral edge sections is called side overlap.

On its underside, a corrugated tile is located on a roof ridge mounted parallel to the ridge, in the region of the head section closer to the ridge. Outside the lowest row directly at the eaves, each tile lies in the region of the top edge portion of a tile adjacent to the eaves in the region of the footrest closest to the eaves. The overlapping region extending over the head flange and the overlapping region extending over the foot flange is called height overlap.

Due to their weight, the tiles rest on the roof substructure. As a result, there is a risk that the tile may rise during a storm. To prevent this, the corrugated tiles can be secured to the roof structure by storm clips. In the case of side-tile corrugated tiles, storm clips, known as a side-tongue clamp, are used which, on the one hand, are hooked to a water-conducting groove adjacent to the height of the foot tile, and on the roof substructure, in particular the roof slats.

On page 103 of the Braas Handbuch 91/93 Geneigte Dácher (Braas Handbook 91/93, Inclined Roofs), these types of storm clips are shown, together with their mounting, mainly a side groove clamp. This side groove clip is formed in two parts and is hooked to a water-guiding groove in a height-overlapping and laterally overlapping corrugated tile with a flat material hooked head. This known storm clamp has a wire-like leg portion hingedly connected to the head portion, the bent end portion of which is nailed to a roof lath.

The installation of this storm clamp is always carried out when the respective tile is laid in a row overlapping in height. Installation is cumbersome because the foot of the storm clamp must always be nailed to the top of the roof, which is located below the eaves edge of the corrugated tiles of the ridge overlapping, so it is already covered.

According to Austrian Patent Application No. 23,119, there is known a storm clamp having an upright curved U-shaped top with its upper stem on the top of an overlapping roof tile. At the end of the lower leg, which is on the underside of the roof tile, there is a wire leg with a handle attached to it. The free end of the toe portion is bent at right angles and has a tip. This curved part is completely folded into a roof top. The foot is not spring-mounted and cannot be mounted without tools. This stormbracket may not always use the same footrest for different distances, but should be made shorter in the case of smaller distances between the roof structure and the roof tile. It is also not possible to adjust the length of the footrest during installation to the actual construction conditions, as the footrest with the handle must be hooked to the headrest before installation.

According to German Application No. 81 34 025, a fastening device for roof tiles is known, wherein a support member fitting into an opening formed on the underside of a roof tile is connected via a spiral spring to a fastening element fixed to the roof tile. The use of this fixing means the use of specially designed roof tiles. The holding force is created solely by the spring force, which depends on the dimensions of the roof tiles, the roof structure and the spring. In the case of tensile stress, the spring can be stretched to any extent, the spring path is not limited.

Another disadvantage of the storm clip described in the introduction is that the distance between the anchor point on the roof bar and the hook-like head is structurally predetermined. However, depending on the particular profile of the tile, the distance between the lower edge of the head edge portion of the tile closer to the ridge on the roof substructure and the upper side of the drainage groove is different. Therefore, different types of wave clips must always be provided for the different types of wave tile, which are adapted to the respective type according to the length of the wire-like leg.

This disadvantage can be overcome by a spring-loaded storm clip described in British Patent No. 1,174,891, the foot of which may be mounted on a roof rail.

Recently, the roof horns have been spaced more apart than before. The greater the distance between two roof rails, the greater the load-bearing capacity of the roof rails. They must therefore be made thicker and / or wider by increasing the distance between their roof corners. Therefore, from the previously described storm clamps, roofing strips of different sizes require specially adapted embodiments.

This disadvantage is overcome by the method described in Swiss Patent No. 202,191, in particular

1, which is also a spring2

EN 214 479 Β are designed to fit. This storm clamp is U-shaped, encircles the roof bar and is hooked at each end of the stem to two water-bearing grooves in the overlapping and overlapping corrugated tiles.

Also known from German utility model G 88 00 485.6 is a spring-shaped, wire-like, storm-clamping bracket having one end connected to a water-conducting groove in a height-tapping corrugated tile, the other end having a plurality of bends, one of which side surface. Various bends are provided for use with roofs of different widths.

In addition, spring storm clips are also known from the "Storm Clips" brochure of FOS, Fr. Ossenberg-Schule + Söhne KG (Altena).

The disadvantage of a spring storm clamp is that the spring force depends on both the profiled tile profile and the size of the roof. A flat tile laid on a thin roof slab is therefore less resistant to storm-induced descent than a heavily profiled and thick slab tile.

SUMMARY OF THE INVENTION The object of the present invention is to provide a storm clamp that is easy to install from the top of the roof without tools and is always of the same design, for both corrugated tiles of different profiles and roofing structures of different sizes, especially roofs of different thickness and / or width can be used for substructures, and the length of the storm clamp can be individually tailored to actual building dimensions during on-site installation so that the tile is always fixed to the roof substructure with the maximum possible tensile force.

The object of the invention is to provide a trough for fixing a tile, which can be mounted on the top of an overlapped tile, preferably in its water-conducting groove, with a hook-like head made of flat material and connected directly thereto in a the head portion being formed to be interconnected at a variable distance from the anchorage location of the foot portion to the roof substructure, in accordance with the present invention, being resolved by engaging the free end of the base leg of the L-shaped leg portion to the roof portion; there is a clamping element for the long leg of the foot, and an upper end section of the foot section extending beyond the clamping member is mounted directly above the clamping member is bent in a corresponding position to form a tensile bond.

In transport condition, the storm clip head of the present invention is disposed near the upper end portion of the long leg of the L-shaped leg portion. During assembly, the headpiece is inserted from the top of the roof into the drainage groove of the last installed tile, the foot portion is led therethrough, and the lower end portion of the foot portion is hooked into the roof substructure. The upper end section of the foot extends sideways beyond the tile because it is so long that, even with a very thick top and very profiled tile, it extends beyond the clamp on the head. Tighten the upper end section by hand so that the base of the foot rests on the roof base. In this position, the upper end portion of the toe portion is bent just above the clamping member to provide a tensile bond between the two portions. An advantage of the storm clip according to the invention is that in this way it is always possible to make an exact individual adjustment of the storm clip to the given conditions, regardless of the actual construction dimensions.

The insertion of the overlapping corrugated tile into the previously C-shaped curved end portion of the previously installed storm clamp is facilitated if the headpiece consists of spring-elastic material. The upper leg of the end section may be inclined upwards at its free end.

In the space between the corrugated tiles, the head section is not worn out when it is made of thin-walled flat material.

For example, the flat leg portion of the storm clamp according to the invention may have a long, vertically extending spacing of 90 °, so that it can be nailed to the flank or eaves side of a roofing strip.

A substantially vertical portion, preferably at an acute angle, of the leg portion of the foregoing storm clamp may be formed at a substantially vertical portion to accommodate the roof structure from below. Such a storm clamp can be attached to the upper side of an already installed corrugated tile and the underside of the roof substructure without an additional fastener, where the curved end section engages on the substructure either on the underside or towards the eaves.

A particularly affordable embodiment of the storm clip is obtained when the leg portion is made of wire-like material.

If the storm clamp requires additional spring action to, for example, compensate for minor changes in length due to the drying or swelling of a wooden roof top, the foot portion is preferably made of spring-elastic material.

Since the bent end portion of the foot part now lies directly on the underside of the roof lath, a maximum tensile force is applied, which corresponds to a strong tensile connection and significantly exceeds the spring force of the bend. However, if the thickness of the wooden roof slats is reduced as a result of drying, the corrugated tile is still secured to the spring force. In the event of a severe storm, the tile may only rise until the bent end of the foot resting again on the underside of the roof top. An increase due to too weak a spring force is therefore impossible. Thus, there is always at least one spring fastening here and, when the spring force is exceeded, a rigid, tensile-resistant connection is formed immediately after a very small distance. In contrast to a non-spring storm clamp, the embodiment of the present invention has the advantage that, even at relatively low wind strengths, there is no ripple effect.

HU 214 479 Β

The storm clip having a head section with a curved end section substantially curved in a C shape (landscape U shape) has the particular advantage that it can also be used to fix wavy streaks on a roof ridge or edge ridge. In this case, the headpiece is mounted on the two ends of two adjacent corrugated tile pots. Because corrugated roof tiles are usually located on adjacent surface surfacing corrugated roof tiles, the roof rail or edge ridge may be omitted if the foot of the storm clamp is secured to adjacent building components of the roof structure.

A particularly simple anchorage in the crotch region may be achieved if the toe portion is substantially W-shaped. The end sections of the foot section can be secured to the top of the roof slats parallel to the ridge, while the middle section is connected to the head section. For example, to compensate for the particularly large distance between the anchorage points on the roof structure and the head portion, the middle region of the W-shaped leg portion may be raised higher than the lateral legs.

The invention will be described in more detail with reference to two preferred embodiments, based on the accompanying drawings.

Figure 1 is a perspective view of a first embodiment of the storm clip according to the invention, obliquely from above, mounted; Figure 2 is a front view of a second embodiment of the storm clip according to the invention during installation; Figure 4 is a side elevation view of the storm clip of Figure 2, while Figure 4 is a larger scale view of the header of the storm clip of Figure 2.

Fig. 1 shows a storm clip 10 according to the invention which is hooked to the upper side of a watertight groove 14 with a head 12 made of a spring-like, spring-elastic flat material, and a L-shaped lower part 18 formed of a spring-elastic wire. is fixed on the underside.

The head portion 12 has an end section 22 substantially curved in lateral view in a U-shaped manner to accommodate a lateral tile overlapping the laterally overlapping tuft 16. The lower portion 24 of the end portion 22 extends substantially horizontally and crosses the groove 14 in a manner adapted to the profile of the groove 14 of the tile 16. The upper leg of the end portion 22 is inclined upwards at its free end.

In the portion 26 of the head portion bent towards the foot portion 18, a clamp 28 is provided for the foot portion 18. The bent section 26 with clamp 28 protrudes in the direction of the roof substructure 20 on the underside of the tile 16. The upper end portion 30 of the long leg of the L-shaped leg portion 18 is inclined at right angles above the clamping member 28, parallel to the waterway groove 14 of the tile, is locked under a projection 32 of the bent section of the head 12 and is positioned below the level of .

The base leg 34 of the L-shaped leg portion 18 is bent at an acute angle to the underside of the roof substructure 20. The free end 36 of the base shank 34 is pointed and formed at a substantially point-like point of attachment to the underside of the roof structure 20, which is formed as a roof slab.

Fig. 2 is a front view of the second embodiment of the storm clip according to the invention with reference 110, from the eaves to the ridge, while Fig. 3 is a side view of the same embodiment. The hook-like, spring-resilient flat material head 112 is hooked here to the upper side of a water-guiding groove 114 of a height-overlapping and laterally overlapping corrugated tile 116 and is secured to the underside 120 of a roof slab 120 formed by a spring-elastic wire.

The head portion 112 of this storm clip 110, shown in magnified form in Figure 4, forms a particularly inexpensive embodiment of a spring steel strip. The head portion 112 is hooked to the upper side 124 of the water guide groove 114 by the hook-shaped end portion 124. Starting from the hook end section 124 is a section 126 which is bent to the roof substructure 120 and is provided with a clamping member 128 for receiving a long leg ending in the upper end section 133 which can be folded into an appropriate position. In the region of the clamping member 128, the spring steel strip is inclined downwardly in the direction opposite to the hook-shaped end section 124 and directly connected thereto in a loop 129 and curved 180 °. In the region of the loop 129, two slots 130, 131 are disposed diametrically opposite each other, starting from one edge of the spring steel strip, into which the leg 118 can be inserted. The lower end portion 132 of the head portion 112 extending from the loop 129 is extended extending below the free end of the hook-shaped end portion 124 so that the head portion 112 is able to engage the waveguide 116 in the region of the conduit groove 114.

As shown in Figure 3, the base leg 134 of the L-shaped leg portion 118 is bent approximately at right angles to the roof substructure 120. As shown in FIG. The free end 136 of the base leg 134 is curved upwardly and this free end 136 is pointed, so that it engages in the underside of the roof structure 120, which is formed as a roof slab, in a manner that is essentially point-like.

Claims (8)

PATENT CLAIMS A storm bracket for fixing a tile, the storm bracket being formed on the top side of an overhanging tile, preferably a water-shaped groove having a hook-like head made of flat material and directly connected to it in a tension-resistant manner; it is formed at a variable distance from the anchorage point of the toe with respect to its anchorage position on the roof structure, Characterized in that the free end (36, 136) of the base leg (34, 134) of the L-shaped leg portion (18, 118) is engageable with the roof substructure (20, 120) and the head portion (12, 112). a clamping element (28,128) is provided on a longitudinal portion (26,126) of the leg portion (18,118), which is inclined towards the leg portion (18,118), and the upper end portion (30,133) extending directly over the head portion (12,112) it is bent in a suitable position above the clamping member (28, 128) to provide tensile resistance. Storm clip according to Claim 1, characterized in that the head part (12, 112) is rigidly connected to the foot part (18, 118) in a pulling direction. Storm clamp according to claim 1 or 2, characterized in that the head part (12, 112) is made of a thin-walled spring-elastic material. Storm clamp according to Claim 3, characterized in that the head part (12) has an upper end section (22) which is curved in a substantially U-shaped manner, which is laterally viewable to accommodate the adjacent overlapping tile. 5. A storm clip according to any one of claims 1 to 4, characterized in that an adjusting device is provided on the head part (12, 112) and / or on the foot part (18, 118) which is provided with a pulling force. 6. Storm clip according to any one of claims 1 to 3, characterized in that the upper end section (30, 133) of the foot section (18, 118) is lockable above the clamping element (28, 128) of the head section (12, 112). 7. The storm clip according to any one of claims 1 to 4, characterized in that the foot part (18, 118) is made of spring-elastic material. 8. A storm clip according to any one of claims 1 to 3, characterized in that the leg portion (18) is made of wire-like material.